2019-02-23 22:00:10 +01:00
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========================
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Decodetree Specification
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========================
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A *decodetree* is built from instruction *patterns*. A pattern may
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represent a single architectural instruction or a group of same, depending
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on what is convenient for further processing.
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Each pattern has both *fixedbits* and *fixedmask*, the combination of which
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describes the condition under which the pattern is matched::
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(insn & fixedmask) == fixedbits
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Each pattern may have *fields*, which are extracted from the insn and
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passed along to the translator. Examples of such are registers,
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immediates, and sub-opcodes.
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In support of patterns, one may declare *fields*, *argument sets*, and
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*formats*, each of which may be re-used to simplify further definitions.
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Fields
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======
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Syntax::
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2019-07-23 02:02:56 +02:00
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field_def := '%' identifier ( unnamed_field )* ( !function=identifier )?
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2019-02-23 22:00:10 +01:00
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unnamed_field := number ':' ( 's' ) number
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For *unnamed_field*, the first number is the least-significant bit position
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of the field and the second number is the length of the field. If the 's' is
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present, the field is considered signed. If multiple ``unnamed_fields`` are
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present, they are concatenated. In this way one can define disjoint fields.
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If ``!function`` is specified, the concatenated result is passed through the
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named function, taking and returning an integral value.
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2019-07-23 02:02:56 +02:00
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One may use ``!function`` with zero ``unnamed_fields``. This case is called
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a *parameter*, and the named function is only passed the ``DisasContext``
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and returns an integral value extracted from there.
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A field with no ``unnamed_fields`` and no ``!function`` is in error.
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2019-02-23 22:00:10 +01:00
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FIXME: the fields of the structure into which this result will be stored
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is restricted to ``int``. Which means that we cannot expand 64-bit items.
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Field examples:
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+---------------------------+---------------------------------------------+
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| Input | Generated code |
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+===========================+=============================================+
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| %disp 0:s16 | sextract(i, 0, 16) |
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+---------------------------+---------------------------------------------+
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| %imm9 16:6 10:3 | extract(i, 16, 6) << 3 | extract(i, 10, 3) |
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+---------------------------+---------------------------------------------+
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| %disp12 0:s1 1:1 2:10 | sextract(i, 0, 1) << 11 | |
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| | extract(i, 1, 1) << 10 | |
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| | extract(i, 2, 10) |
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+---------------------------+---------------------------------------------+
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| %shimm8 5:s8 13:1 | expand_shimm8(sextract(i, 5, 8) << 1 | |
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| !function=expand_shimm8 | extract(i, 13, 1)) |
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+---------------------------+---------------------------------------------+
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Argument Sets
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=============
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Syntax::
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args_def := '&' identifier ( args_elt )+ ( !extern )?
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args_elt := identifier
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Each *args_elt* defines an argument within the argument set.
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Each argument set will be rendered as a C structure "arg_$name"
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with each of the fields being one of the member arguments.
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If ``!extern`` is specified, the backing structure is assumed
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to have been already declared, typically via a second decoder.
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2019-02-28 03:34:38 +01:00
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Argument sets are useful when one wants to define helper functions
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for the translator functions that can perform operations on a common
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set of arguments. This can ensure, for instance, that the ``AND``
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pattern and the ``OR`` pattern put their operands into the same named
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structure, so that a common ``gen_logic_insn`` may be able to handle
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the operations common between the two.
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2019-02-23 22:00:10 +01:00
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Argument set examples::
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®3 ra rb rc
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&loadstore reg base offset
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Formats
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=======
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Syntax::
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fmt_def := '@' identifier ( fmt_elt )+
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fmt_elt := fixedbit_elt | field_elt | field_ref | args_ref
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fixedbit_elt := [01.-]+
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field_elt := identifier ':' 's'? number
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field_ref := '%' identifier | identifier '=' '%' identifier
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args_ref := '&' identifier
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Defining a format is a handy way to avoid replicating groups of fields
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across many instruction patterns.
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A *fixedbit_elt* describes a contiguous sequence of bits that must
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be 1, 0, or don't care. The difference between '.' and '-'
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is that '.' means that the bit will be covered with a field or a
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final 0 or 1 from the pattern, and '-' means that the bit is really
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ignored by the cpu and will not be specified.
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A *field_elt* describes a simple field only given a width; the position of
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the field is implied by its position with respect to other *fixedbit_elt*
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and *field_elt*.
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If any *fixedbit_elt* or *field_elt* appear, then all bits must be defined.
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Padding with a *fixedbit_elt* of all '.' is an easy way to accomplish that.
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A *field_ref* incorporates a field by reference. This is the only way to
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add a complex field to a format. A field may be renamed in the process
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via assignment to another identifier. This is intended to allow the
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same argument set be used with disjoint named fields.
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A single *args_ref* may specify an argument set to use for the format.
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The set of fields in the format must be a subset of the arguments in
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the argument set. If an argument set is not specified, one will be
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inferred from the set of fields.
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It is recommended, but not required, that all *field_ref* and *args_ref*
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appear at the end of the line, not interleaving with *fixedbit_elf* or
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*field_elt*.
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Format examples::
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@opr ...... ra:5 rb:5 ... 0 ....... rc:5
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@opi ...... ra:5 lit:8 1 ....... rc:5
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Patterns
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========
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Syntax::
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pat_def := identifier ( pat_elt )+
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pat_elt := fixedbit_elt | field_elt | field_ref | args_ref | fmt_ref | const_elt
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fmt_ref := '@' identifier
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const_elt := identifier '=' number
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The *fixedbit_elt* and *field_elt* specifiers are unchanged from formats.
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A pattern that does not specify a named format will have one inferred
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from a referenced argument set (if present) and the set of fields.
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A *const_elt* allows a argument to be set to a constant value. This may
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come in handy when fields overlap between patterns and one has to
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include the values in the *fixedbit_elt* instead.
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The decoder will call a translator function for each pattern matched.
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Pattern examples::
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addl_r 010000 ..... ..... .... 0000000 ..... @opr
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addl_i 010000 ..... ..... .... 0000000 ..... @opi
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which will, in part, invoke::
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trans_addl_r(ctx, &arg_opr, insn)
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and::
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trans_addl_i(ctx, &arg_opi, insn)
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2019-02-23 20:35:36 +01:00
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Pattern Groups
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==============
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Syntax::
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2020-08-03 22:57:08 +02:00
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group := overlap_group | no_overlap_group
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overlap_group := '{' ( pat_def | group )+ '}'
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no_overlap_group := '[' ( pat_def | group )+ ']'
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A *group* begins with a lone open-brace or open-bracket, with all
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subsequent lines indented two spaces, and ending with a lone
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close-brace or close-bracket. Groups may be nested, increasing the
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required indentation of the lines within the nested group to two
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spaces per nesting level.
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Patterns within overlap groups are allowed to overlap. Conflicts are
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resolved by selecting the patterns in order. If all of the fixedbits
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for a pattern match, its translate function will be called. If the
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translate function returns false, then subsequent patterns within the
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group will be matched.
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Patterns within no-overlap groups are not allowed to overlap, just
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the same as ungrouped patterns. Thus no-overlap groups are intended
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to be nested inside overlap groups.
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2019-02-23 20:35:36 +01:00
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The following example from PA-RISC shows specialization of the *or*
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instruction::
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{
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{
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nop 000010 ----- ----- 0000 001001 0 00000
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copy 000010 00000 r1:5 0000 001001 0 rt:5
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}
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or 000010 rt2:5 r1:5 cf:4 001001 0 rt:5
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}
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When the *cf* field is zero, the instruction has no side effects,
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and may be specialized. When the *rt* field is zero, the output
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is discarded and so the instruction has no effect. When the *rt2*
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2020-08-03 22:57:08 +02:00
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field is zero, the operation is ``reg[r1] | 0`` and so encodes
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2019-02-23 20:35:36 +01:00
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the canonical register copy operation.
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The output from the generator might look like::
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switch (insn & 0xfc000fe0) {
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case 0x08000240:
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/* 000010.. ........ ....0010 010..... */
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if ((insn & 0x0000f000) == 0x00000000) {
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/* 000010.. ........ 00000010 010..... */
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if ((insn & 0x0000001f) == 0x00000000) {
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/* 000010.. ........ 00000010 01000000 */
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extract_decode_Fmt_0(&u.f_decode0, insn);
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if (trans_nop(ctx, &u.f_decode0)) return true;
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}
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if ((insn & 0x03e00000) == 0x00000000) {
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/* 00001000 000..... 00000010 010..... */
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extract_decode_Fmt_1(&u.f_decode1, insn);
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if (trans_copy(ctx, &u.f_decode1)) return true;
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}
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}
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extract_decode_Fmt_2(&u.f_decode2, insn);
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if (trans_or(ctx, &u.f_decode2)) return true;
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return false;
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}
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